/*
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package Tiempo;

import java.text.DecimalFormat;
import java.text.SimpleDateFormat;
import java.util.Date;

/**
 * This class represents a NTP message, as specified in RFC 2030.  The message
 * format is compatible with all versions of NTP and SNTP.
 *
 * This class does not support the optional authentication protocol, and
 * ignores the key ID and message digest fields.
 * 
 * For convenience, this class exposes message values as native Java types, not
 * the NTP-specified data formats.  For example, timestamps are
 * stored as doubles (as opposed to the NTP unsigned 64-bit fixed point
 * format).
 * 
 * However, the contructor NtpMessage(byte[]) and the method toByteArray()
 * allow the import and export of the raw NTP message format.
 * 
 * 
 * Usage example
 * 
 * // Send message
 * DatagramSocket socket = new DatagramSocket();
 * InetAddress address = InetAddress.getByName("ntp.cais.rnp.br");
 * byte[] buf = new NtpMessage().toByteArray();
 * DatagramPacket packet = new DatagramPacket(buf, buf.length, address, 123);
 * socket.send(packet);
 * 
 * // Get response
 * socket.receive(packet);
 * System.out.println(msg.toString());
 * 
 *  
 * This code is copyright (c) Adam Buckley 2004
 *
 * This program is free software; you can redistribute it and/or modify it 
 * under the terms of the GNU General Public License as published by the Free 
 * Software Foundation; either version 2 of the License, or (at your option) 
 * any later version.  A HTML version of the GNU General Public License can be
 * seen at http://www.gnu.org/licenses/gpl.html
 *
 * This program is distributed in the hope that it will be useful, but WITHOUT 
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or 
 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for 
 * more details.
 * 
 * 
 * Comments for member variables are taken from RFC2030 by David Mills,
 * University of Delaware.
 * 
 * Number format conversion code in NtpMessage(byte[] array) and toByteArray()
 * inspired by http://www.pps.jussieu.fr/~jch/enseignement/reseaux/
 * NTPMessage.java which is copyright (c) 2003 by Juliusz Chroboczek
 * 
 * @author Adam Buckley
 */
public class NtpMessage {
    /**
     * This is a two-bit code warning of an impending leap second to be
     * inserted/deleted in the last minute of the current day.  It's values
     * may be as follows:
     * 
     * Value     Meaning
     * -----     -------
     * 0         no warning
     * 1         last minute has 61 seconds
     * 2         last minute has 59 seconds)
     * 3         alarm condition (clock not synchronized)
     */
    public byte leapIndicator = 0;
     
     
    /**
     * This value indicates the NTP/SNTP version number.  The version number
     * is 3 for Version 3 (IPv4 only) and 4 for Version 4 (IPv4, IPv6 and OSI).
     * If necessary to distinguish between IPv4, IPv6 and OSI, the
     * encapsulating context must be inspected.
     */
    public byte version = 3;
     
     
    /**
     * This value indicates the mode, with values defined as follows:
     * 
     * Mode     Meaning
     * ----     -------
     * 0        reserved
     * 1        symmetric active
     * 2        symmetric passive
     * 3        client
     * 4        server
     * 5        broadcast
     * 6        reserved for NTP control message
     * 7        reserved for private use
     * 
     * In unicast and anycast modes, the client sets this field to 3 (client)
     * in the request and the server sets it to 4 (server) in the reply. In
     * multicast mode, the server sets this field to 5 (broadcast).
     */
    public byte mode = 0;
     
     
    /**
     * This value indicates the stratum level of the local clock, with values
     * defined as follows:
     * 
     * Stratum  Meaning
     * ----------------------------------------------
     * 0        unspecified or unavailable
     * 1        primary reference (e.g., radio clock)
     * 2-15     secondary reference (via NTP or SNTP)
     * 16-255   reserved
     */
    public short stratum = 0;
     
 
    /**
     * This value indicates the maximum interval between successive messages,
     * in seconds to the nearest power of two. The values that can appear in
     * this field presently range from 4 (16 s) to 14 (16284 s); however, most
     * applications use only the sub-range 6 (64 s) to 10 (1024 s).
     */
    public byte pollInterval = 0;
     
     
    /**
     * This value indicates the precision of the local clock, in seconds to
     * the nearest power of two.  The values that normally appear in this field
     * range from -6 for mains-frequency clocks to -20 for microsecond clocks
     * found in some workstations.
     */
    public byte precision = 0;
     
     
    /**
     * This value indicates the total roundtrip delay to the primary reference
     * source, in seconds.  Note that this variable can take on both positive
     * and negative values, depending on the relative time and frequency
     * offsets. The values that normally appear in this field range from
     * negative values of a few milliseconds to positive values of several
     * hundred milliseconds.
     */
    public double rootDelay = 0;
     
     
    /**
     * This value indicates the nominal error relative to the primary reference
     * source, in seconds.  The values  that normally appear in this field
     * range from 0 to several hundred milliseconds.
     */
    public double rootDispersion = 0;
     
     
    /**
     * This is a 4-byte array identifying the particular reference source.
     * In the case of NTP Version 3 or Version 4 stratum-0 (unspecified) or
     * stratum-1 (primary) servers, this is a four-character ASCII string, left
     * justified and zero padded to 32 bits. In NTP Version 3 secondary
     * servers, this is the 32-bit IPv4 address of the reference source. In NTP
     * Version 4 secondary servers, this is the low order 32 bits of the latest
     * transmit timestamp of the reference source. NTP primary (stratum 1)
     * servers should set this field to a code identifying the external
     * reference source according to the following list. If the external
     * reference is one of those listed, the associated code should be used.
     * Codes for sources not listed can be contrived as appropriate.
     * 
     * Code     External Reference Source
     * ----     -------------------------
     * LOCL     uncalibrated local clock used as a primary reference for
     *          a subnet without external means of synchronization
     * PPS      atomic clock or other pulse-per-second source
     *          individually calibrated to national standards
     * ACTS     NIST dialup modem service
     * USNO     USNO modem service
     * PTB      PTB (Germany) modem service
     * TDF      Allouis (France) Radio 164 kHz
     * DCF      Mainflingen (Germany) Radio 77.5 kHz
     * MSF      Rugby (UK) Radio 60 kHz
     * WWV      Ft. Collins (US) Radio 2.5, 5, 10, 15, 20 MHz
     * WWVB     Boulder (US) Radio 60 kHz
     * WWVH     Kaui Hawaii (US) Radio 2.5, 5, 10, 15 MHz
     * CHU      Ottawa (Canada) Radio 3330, 7335, 14670 kHz
     * LORC     LORAN-C radionavigation system
     * OMEG     OMEGA radionavigation system
     * GPS      Global Positioning Service
     * GOES     Geostationary Orbit Environment Satellite
     */
    public byte[] referenceIdentifier = {0, 0, 0, 0};
     
     
    /**
     * This is the time at which the local clock was last set or corrected, in
     * seconds since 00:00 1-Jan-1900.
     */
    public double referenceTimestamp = 0;
     
     
    /**
     * This is the time at which the request departed the client for the
     * server, in seconds since 00:00 1-Jan-1900.
     */
    public double originateTimestamp = 0;
     
     
    /**
     * This is the time at which the request arrived at the server, in seconds
     * since 00:00 1-Jan-1900.
     */
    public double receiveTimestamp = 0;
     
     
    /**
     * This is the time at which the reply departed the server for the client,
     * in seconds since 00:00 1-Jan-1900.
     */
    public double transmitTimestamp = 0;
     
     
     
    /**
     * Constructs a new NtpMessage from an array of bytes.
     */
    public NtpMessage(byte[] array)
    {
        // See the packet format diagram in RFC 2030 for details 
        leapIndicator = (byte) ((array[0] >> 6) & 0x3);
        version = (byte) ((array[0] >> 3) & 0x7);
        mode = (byte) (array[0] & 0x7);
        stratum = unsignedByteToShort(array[1]);
        pollInterval = array[2];
        precision = array[3];
         
        rootDelay = (array[4] * 256.0) + 
            unsignedByteToShort(array[5]) +
            (unsignedByteToShort(array[6]) / 256.0) +
            (unsignedByteToShort(array[7]) / 65536.0);
         
        rootDispersion = (unsignedByteToShort(array[8]) * 256.0) + 
            unsignedByteToShort(array[9]) +
            (unsignedByteToShort(array[10]) / 256.0) +
            (unsignedByteToShort(array[11]) / 65536.0);
         
        referenceIdentifier[0] = array[12];
        referenceIdentifier[1] = array[13];
        referenceIdentifier[2] = array[14];
        referenceIdentifier[3] = array[15];
         
        referenceTimestamp = decodeTimestamp(array, 16);
        originateTimestamp = decodeTimestamp(array, 24);
        receiveTimestamp = decodeTimestamp(array, 32);
        transmitTimestamp = decodeTimestamp(array, 40);
    }
     
     
     
    /**
     * Constructs a new NtpMessage in client -> server mode, and sets the
     * transmit timestamp to the current time.
     */
    public NtpMessage()
    {
        // Note that all the other member variables are already set with
        // appropriate default values.
        this.mode = 3;
        this.transmitTimestamp = (System.currentTimeMillis()/1000.0) + 2208988800.0; 
    }
     
     
     
    /**
     * This method constructs the data bytes of a raw NTP packet.
     */
    public byte[] toByteArray()
    {
        // All bytes are automatically set to 0
        byte[] p = new byte[48];
 
        p[0] = (byte) (leapIndicator << 6 | version << 3 | mode);
        p[1] = (byte) stratum;
        p[2] = (byte) pollInterval;
        p[3] = (byte) precision;
         
        // root delay is a signed 16.16-bit FP, in Java an int is 32-bits
        int l = (int) (rootDelay * 65536.0);
        p[4] = (byte) ((l >> 24) & 0xFF);
        p[5] = (byte) ((l >> 16) & 0xFF);
        p[6] = (byte) ((l >> 8) & 0xFF);
        p[7] = (byte) (l & 0xFF);
         
        // root dispersion is an unsigned 16.16-bit FP, in Java there are no
        // unsigned primitive types, so we use a long which is 64-bits 
        long ul = (long) (rootDispersion * 65536.0);
        p[8] = (byte) ((ul >> 24) & 0xFF);
        p[9] = (byte) ((ul >> 16) & 0xFF);
        p[10] = (byte) ((ul >> 8) & 0xFF);
        p[11] = (byte) (ul & 0xFF);
         
        p[12] = referenceIdentifier[0];
        p[13] = referenceIdentifier[1];
        p[14] = referenceIdentifier[2];
        p[15] = referenceIdentifier[3];
         
        encodeTimestamp(p, 16, referenceTimestamp);
        encodeTimestamp(p, 24, originateTimestamp);
        encodeTimestamp(p, 32, receiveTimestamp);
        encodeTimestamp(p, 40, transmitTimestamp);
         
        return p; 
    }
     
     
     
    /**
     * Returns a string representation of a NtpMessage
     */
    public String toString()
    {
        String precisionStr =
            new DecimalFormat("0.#E0").format(Math.pow(2, precision));
             
        return "Leap indicator: " + leapIndicator + "\n" +
            "Version: " + version + "\n" +
            "Mode: " + mode + "\n" +
            "Stratum: " + stratum + "\n" +
            "Poll: " + pollInterval + "\n" +
            "Precision: " + precision + " (" + precisionStr + " seconds)\n" + 
            "Root delay: " + new DecimalFormat("0.00").format(rootDelay*1000) + " ms\n" +
            "Root dispersion: " + new DecimalFormat("0.00").format(rootDispersion*1000) + " ms\n" + 
            "Reference identifier: " + referenceIdentifierToString(referenceIdentifier, stratum, version) + "\n" +
            "Reference timestamp: " + timestampToString(referenceTimestamp) + "\n" +
            "Originate timestamp: " + timestampToString(originateTimestamp) + "\n" +
            "Receive timestamp:   " + timestampToString(receiveTimestamp) + "\n" +
            "Transmit timestamp:  " + timestampToString(transmitTimestamp);
    }
     
     
     
    /**
     * Converts an unsigned byte to a short.  By default, Java assumes that
     * a byte is signed.
     */
    public static short unsignedByteToShort(byte b)
    {
        if((b & 0x80)==0x80) return (short) (128 + (b & 0x7f));
        else return (short) b;
    }
     
     
     
    /**
     * Will read 8 bytes of a message beginning at <code>pointer</code>
     * and return it as a double, according to the NTP 64-bit timestamp
     * format.
     */
    public static double decodeTimestamp(byte[] array, int pointer)
    {
        double r = 0.0;
         
        for(int i=0; i<8; i++)
        {
            r += unsignedByteToShort(array[pointer+i]) * Math.pow(2, (3-i)*8);
        }
         
        return r;
    }
     
     
     
    /**
     * Encodes a timestamp in the specified position in the message
     */
    public static void encodeTimestamp(byte[] array, int pointer, double timestamp)
    {
        // Converts a double into a 64-bit fixed point
        for(int i=0; i<8; i++)
        {
            // 2^24, 2^16, 2^8, .. 2^-32
            double base = Math.pow(2, (3-i)*8);
             
            // Capture byte value
            array[pointer+i] = (byte) (timestamp / base);
 
            // Subtract captured value from remaining total
            timestamp = timestamp - (double) (unsignedByteToShort(array[pointer+i]) * base);
        }
         
        // From RFC 2030: It is advisable to fill the non-significant
        // low order bits of the timestamp with a random, unbiased
        // bitstring, both to avoid systematic roundoff errors and as
        // a means of loop detection and replay detection.
        array[7] = (byte) (Math.random()*255.0);
    }
     
     
     
    /**
     * Returns a timestamp (number of seconds since 00:00 1-Jan-1900) as a
     * formatted date/time string. 
     */
    public static String timestampToString(double timestamp)
    {
        if(timestamp==0) return "0";
         
        // timestamp is relative to 1900, utc is used by Java and is relative
        // to 1970 
        double utc = timestamp - (2208988800.0);
         
        // milliseconds
        long ms = (long) (utc * 1000.0);
         
        // date/time
        String date = new SimpleDateFormat("dd-MMM-yyyy HH:mm:ss").format(new Date(ms));
         
        // fraction
        double fraction = timestamp - ((long) timestamp);
        String fractionSting = new DecimalFormat(".000000").format(fraction);
         
        return date + fractionSting;
    }
    /**
     * da el objeto date de la fecha obtenida
     * @param timestamp
     * @return 
     */
    public Date timestampToDate(double timestamp){
                
        // timestamp is relative to 1900, utc is used by Java and is relative
        // to 1970 
        double utc = timestamp - (2208988800.0);
         
        // milliseconds
        long ms = (long) (utc * 1000.0);
        
        return new Date(ms);
    }
     
     
     
    /**
     * Returns a string representation of a reference identifier according
     * to the rules set out in RFC 2030.
     */
    public static String referenceIdentifierToString(byte[] ref, short stratum, byte version)
    {
        // From the RFC 2030:
        // In the case of NTP Version 3 or Version 4 stratum-0 (unspecified)
        // or stratum-1 (primary) servers, this is a four-character ASCII
        // string, left justified and zero padded to 32 bits.
        if(stratum==0 || stratum==1)
        {
            return new String(ref);
        }
         
        // In NTP Version 3 secondary servers, this is the 32-bit IPv4
        // address of the reference source.
        else if(version==3)
        {
            return unsignedByteToShort(ref[0]) + "." +
                unsignedByteToShort(ref[1]) + "." +
                unsignedByteToShort(ref[2]) + "." +
                unsignedByteToShort(ref[3]);
        }
         
        // In NTP Version 4 secondary servers, this is the low order 32 bits
        // of the latest transmit timestamp of the reference source.
        else if(version==4)
        {
            return "" + ((unsignedByteToShort(ref[0]) / 256.0) + 
                (unsignedByteToShort(ref[1]) / 65536.0) +
                (unsignedByteToShort(ref[2]) / 16777216.0) +
                (unsignedByteToShort(ref[3]) / 4294967296.0));
        }
         
        return "";
    }
}
